Multi-layered solid electrolytic capacitor and method of manufacturing same

ABSTRACT

[Problem] A multi-layered solid electrolytic capacitor and a method of manufacturing the capacitor are provided that make it possible to improve the product yield drastically by preventing increases in leakage current and defects due to short circuits without increasing manufacturing cost or capacitor size. 
     [Means for Solving the Problem] A multi-layered solid electrolytic capacitor includes: a plurality of capacitor elements  6 , each being furnished with an aluminum foil  1  having an anode portion  7  and a cathode portion  8  having a dielectric oxide film  2  and a cathode layer  3  formed in succession on a surface of the aluminum foil  1 , wherein the plurality of capacitor elements  6  are stacked on top of one another, the anode portions  7  of adjacent capacitor elements  6  are welded each other, and the anode portion  7  of one of the outermost capacitor elements  6  is weld-secured to an anode terminal  12 , the multi-layered solid electrolytic capacitor being characterized in that a first stress alleviating slit  16  and a second stress alleviating slit  17  are formed in at least one of weld surfaces of the anode portion  7.

TECHNICAL FIELD

The present invention relates to multi-layered solid electrolytic capacitors and methods of manufacturing the same, and particularly to a multi-layered solid electrolytic capacitor that can improve the product yield and a method of manufacturing the same.

BACKGROUND ART

A conventional multi-layered solid electrolytic capacitor has been fabricated in the following manner. As illustrated in FIG. 14, a dielectric oxide film 2 and a cathode layer 3 composed of a solid electrolyte layer 3 a, a carbon layer 3 b, and a silver paint layer 3 c are successively formed over a surface of an aluminum foil 1, which is a valve metal, to prepare a capacitor element 6. Subsequently, as illustrated in FIG. 15, a plurality of the capacitor elements 6 in a stacked condition is connected to an anode terminal 12 by resistance welding, and they are connected to a cathode terminal 13 by a conductive adhesive 18. Finally, these components are covered with an exterior resin 14 to produce a multi-layered solid electrolytic capacitor.

When stacking the capacitor element 6, first, a capacitor element 6 is held at its cathode portion 8, and conveyed and placed onto a lead frame. Thereafter, the anode portion 7 of the capacitor element 6 is connected to the anode terminal 12 by resistance welding, and then, the connected anode portion 7 of the capacitor element 6 is welded to the anode portion 7 of another capacitor element 6 to be stacked thereover. The capacitor elements are stacked by repeating the above-described processes (see Patent Reference 1).

[Patent Reference 1] Japanese Published Unexamined Patent Application No. 11-135367

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention

In the just-mentioned conventional multi-layered solid electrolytic capacitor, however, the thickness L11 of the anode portion 7 ≈100 μm and the thickness L12 of the cathode portion 8 is ≈200 μm, as shown in FIG. 14, so there is a large difference between the thickness L11 of the anode portion 7 and the thickness L12 of the cathode portion 8. Consequently, a bend forms at the boundary between the anode portion 7 and the cathode portion 8 as illustrated in FIG. 15. As a consequence, tensile stress and bending stress act on the boundary between the anode portion 7 and the cathode portion 8 or on the vicinity thereof (indicated by reference numeral 50 in FIG. 15) during the resistance welding, and the stresses build up in that part. Thus, cracks develop at the boundary between the anode portion 7 and the cathode portion 8 or in the anode portion 7 that is in the vicinity thereof, causing increases in leakage current of the capacitor or defects due to short circuits. This is especially noticeable in the capacitor elements 6 that are disposed more distant from the anode terminal 12.

Taking these things into consideration, it may appear conceivable to employ a structure in which a resin is applied or a tape is attached in the vicinity of the boundary between the anode portion 7 and the cathode portion 8. However, even when such a structure is employed, it is difficult to alleviate the stress that acts on the boundary between the anode portion 7 and the cathode portion 8 sufficiently. Moreover, in the case that a resin is applied, additional problems arise as follows; each capacitor element 6 becomes thick and accordingly the size of the multi-layered solid electrolytic capacitor increases (specifically, the height increases), and the manufacturing cost rises because an additional drying process becomes necessary in addition to the material cost for the resin. On the other hand, in the case of attaching a tape, additional problems arise as follows; precise bonding of the tape is troublesome and the size of the multi-layered solid electrolytic capacitor increases, as in the case of applying a resin.

The present invention has been accomplished in view of the foregoing circumstances, and it is an object of the invention to provide a multi-layered solid electrolytic capacitor and a method of manufacturing the capacitor that make it possible to improve the product yield drastically by preventing increases in leakage current and defects due to short circuits without increasing the manufacturing cost or the capacitor size.

Means for Solving the Problems

In order to accomplish the foregoing object, the invention as set forth in claim 1 provides a multi-layered solid electrolytic capacitor comprising: a plurality of capacitor elements, each comprising an anode body having an anode portion and a cathode portion having a dielectric oxide film and a cathode layer formed in succession on a surface of the anode body, wherein the plurality of capacitor elements are stacked on top of one another, the anode portions of adjacent capacitor elements are welded each other, and the anode portion of one of the outermost capacitor elements is weld-secured to an anode terminal, the multi-layered solid electrolytic capacitor being characterized in that: a stress alleviating slit and/or a stress alleviating hole is/are formed in between a welded part and the boundary between the anode and cathode portions in at least one of weld surfaces of the anode portion.

When a stress alleviating slit and/or a stress alleviating hole is/are formed in between a welded part and the boundary between the anode and cathode portions in at least one of weld surfaces of the anode portion, the physical strength of the vicinity reduces, and the anode portion bends in the vicinity of the stress alleviating slit or the stress alleviating hole during the resistance welding. Thus, the bending stress that acts on the boundary between the anode portion and the cathode portion or on the vicinity thereof reduces, and therefore, the stresses that act on that part reduces accordingly. As a result, it becomes possible to prevent an increase in leakage current of the capacitor and defects due to short circuits, which result from the cracks that develop at the boundary between the anode portion and the cathode portion or in the anode portion that is in the vicinity thereof.

Since it is only necessary to form the stress alleviating slit and so forth, the problem of size increase of the multi-layered solid electrolytic capacitor does not arise, and also, the manufacturing costs do not rise.

Moreover, in the case that the stress alleviating hole is provided, the stress alleviating hole is provided between a resistance part and the boundary between the anode and cathode portions, and therefore, the heat applied during the welding can be prevented from escaping toward the cathode portion. As a result, the welding can be accomplished with a less heat quantity, so the advantageous effect of improved weldability is exhibited additionally.

The invention as set forth in claim 2 is characterized in that, in the invention as set forth in claim 1, the stress alleviating hole forms an oblong shape.

When the stress alleviating hole has an oblong shape in this way, the anode portion bends unfailingly at a predetermined position without degrading the strength of the region in which the stress alleviating hole is provided. The reason is as follows. For example, if the stress alleviating hole has a rectangular shape, cracks tend to develop at the four corners. If the stress alleviating hole has a perfect circular shape, the position at which the anode portion bends in the circular portion is not constant, and moreover, the diameter has to be small since the gap between the welded part and the boundary between the anode and cathode portions is not very large, in which case the stress alleviating effect may not be sufficient. In contrast, these inconveniences can be avoided when the stress alleviating hole has an oblong shape.

It should be noted that the oblong shape is meant to include elliptical shapes and the like.

The invention as set forth in claim 3 is characterized in that, in the invention as set forth in claim 1 or 2, the major axis of the stress alleviating slit or the stress alleviating hole is substantially parallel to the boundary between the anode and cathode portions.

When the major axis of the stress alleviating slit or the stress alleviating hole is not parallel to the boundary between the anode and cathode portions, the stress at one end part of the stress alleviating slit or the like becomes greater and cracks may develop from that part. On the other hand, when the major axis of the stress alleviating slit or the like is parallel to the boundary between the cathode portion and the foregoing anode portion, stresses act on the entire stress alleviating slit or the like, making it possible to prevent the cracks from developing in the stress alleviating slit or the like.

The invention as set forth in claim 4 is characterized in that, in the invention as set forth in claim 1 or 3, the stress alleviating slit is formed in an anode terminal-side surface of the weld surfaces of the anode portion.

The anode terminal-side surface of the weld surfaces of the anode portion has a greater curvature than that of the other surface by the thickness of the anode portion, so the anode terminal-side surface receives a greater stress. For this reason, a greater stress alleviating effect can be obtained by forming the stress alleviating slit in the anode terminal-side surface.

The invention as set forth in claim 5 is characterized in that, in the invention as set forth in any one of claims 1 through 4, the stress alleviating slit or the stress alleviating hole is formed in the capacitor elements other than the capacitor element weld-secured to the anode terminal.

The reason why such a restriction is made is as follows. The tilt angle of the anode portion extending from the cathode portion is 0° or extremely small in the capacitor element that is weld-secured to the anode terminal, so the bending stress at the boundary between the cathode portion and the anode portion or in the vicinity thereof is small. On the other hand, in the capacitor elements other than the capacitor element weld-secured to the anode terminal, the tilt angle of the anode portion extending from the cathode portion is greater by the difference of the thickness of the cathode portions and the anode portions of the capacitor elements that exist nearer the anode terminal side than the foregoing capacitor element, so the bending stresses at the boundary between the cathode portion and the anode portion or in the vicinity thereof are greater.

The invention as set forth in claim 6 is characterized in that, in the invention as set forth in any one of claims 1 through 5, the stress alleviating slit or the stress alleviating hole is so formed that the more distant the anode portion is from the anode terminal, the greater the area of the stress alleviating slit or the stress alleviating hole in the weld surface.

As mentioned above, the more distant the anode portion is from the anode terminal, the greater the tilt angle of the anode portion that extends from the cathode portion will be. Therefore, the bending stresses at the boundary between the cathode portion and the anode portion or in the vicinity thereof are great. Accordingly, the stress alleviating effect corresponding to the intensity of the stress can be obtained when the stress alleviating slit or the stress alleviating hole is so formed that the more distant the anode portion is from the anode terminal, the greater the area of the stress alleviating slit or the stress alleviating hole in the weld surface.

The invention as set forth in claim 7 is characterized in that, in the invention as set forth in any one of claims 1 through 6, at least one capacitor element is provided in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed.

When at least one capacitor element is provided in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed, the physical strength in the vicinity of the stress alleviating slit or the like reduces further, and therefore, a greater stress alleviating effect is obtained.

The invention as set forth in claim 8 is characterized in that, in the invention as set forth in claim 7, when the multi-layered solid electrolytic capacitor comprises a plurality of capacitor elements in which a plurality of the stress alleviating slits or the stress alleviating holes are formed, the stress alleviating slits or the stress alleviating holes are so formed that the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating slits or the stress alleviating holes.

As mentioned above, the more distant the anode portion is from the anode terminal, the greater the tilt angle of the anode portion that extends from the cathode portion will be. Therefore, the bending stresses at the boundary between the cathode portion and the anode portion or in the vicinity thereof are great. Accordingly, the stress alleviating effect corresponding to the intensity of the stress can be obtained when the stress alleviating slits or the stress alleviating holes are so formed that the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating slits or the stress alleviating holes.

The invention as set forth in claim 9 is characterized in that, in the invention as set forth in any one of claims 1 through 8, when the multi-layered solid electrolytic capacitor comprises both the stress alleviating slit and the stress alleviating hole, the stress alleviating slit is provided so as to be joined to the stress alleviating hole.

When only the stress alleviating hole is provided, the bend position in the area in which the stress alleviating hole does not exist may not be consistent. When the stress alleviating slit is provided so as to be joined to the stress alleviating hole as described above, the anode portion can be bent at a predetermined position even in the area in which the stress alleviating hole does not exist.

In order to accomplish the foregoing objects, the present invention as set forth in claim 10 provides a method of manufacturing a multi-layered solid electrolytic capacitor, comprising: a first step of preparing capacitor elements each comprising an anode portion and a cathode portion in which a dielectric oxide film and a cathode layer are formed successively over a surface of an anode body; a second step of forming a stress alleviating slit and/or a stress alleviating hole in at least one weld surface of the anode portion; a third step of weld-securing an anode terminal to the anode portion of one of the capacitor elements; and a fourth step of, in a state where another capacitor element is stacked on the one of the capacitor element weld-secured the anode terminal, weld-securing anode portions of adjacent capacitor elements to each other.

The just-described method makes it possible to easily manufacture a multi-layered solid electrolytic capacitor as set forth in claim 1.

The invention as set forth in claim 11 is characterized in that, in the second step in the invention as set forth in claim 10, the stress alleviating slit and/or the stress alleviating hole is/are formed by a laser application method.

When the stress alleviating slit or the like is formed by a laser application method as described above, the stress alleviating slit or the like can be formed reliably and quickly. Moreover, when the oxide film in the stack and weld part is removed by the laser method, the problem of an increase in the manufacturing steps does not arise.

It should be noted that whether the stress alleviating hole or the stress alleviating slit is formed may be realized by adjusting the laser beam diameter, the laser power, and so forth.

The invention as set forth in claim 12 is characterized in that, in the second step in the invention as set forth in claim 10 or 11, the stress alleviating hole is formed in a weld surface of the anode portion and the stress alleviating slit is formed in at least one weld surface of the anode portion so as to be joined to the stress alleviating hole.

The just-described method makes it possible to easily manufacture a multi-layered solid electrolytic capacitor as set forth in claim 9.

ADVANTAGES OF THE INVENTION

The present invention exhibits significant advantageous effects that the product yield of the multi-layered solid electrolytic capacitor can be drastically improved by preventing increases in leakage current and defects due to short circuits without increasing the manufacturing cost or the capacitor size.

BEST MODE FOR CARRYING OUT THE INVENTION

It should be construed that the multi-layered solid electrolytic capacitor according to the present invention is not limited to those shown in the following embodiments, and various changes and modifications are possible without departing from the scope of the invention.

First Embodiment (Structure of Multi-Layered Solid Electrolytic Capacitor)

A multi-layered solid electrolytic capacitor according to a first embodiment is described in detail with reference to FIGS. 1 through 6. FIG. 1 is a vertical cross-sectional view of a multi-layered solid electrolytic capacitor according to the first embodiment. FIG. 2 is a plan view of a capacitor element used in the first embodiment. FIG. 3 is a cross-sectional view taken along line A-A in FIG. 2. FIG. 4 is a cross-sectional view illustrating a primary portion enlarged of a capacitor element used in the first embodiment. FIG. 5 is a cross-sectional view illustrating a primary portion enlarged of the multi-layered solid electrolytic capacitor according to the first embodiment. FIG. 6 is a plan view illustrating a manufacturing step of the multi-layered solid electrolytic capacitor according to the first embodiment.

As illustrated in FIG. 1, a multi-layered solid electrolytic capacitor 10 is furnished with a plurality of sheets (four sheets in this example) of capacitor elements 6 stacked on top of one another, and an anode terminal 12 and a cathode terminal 13 are attached to the lower face of the capacitor element 6 that is in the lowermost position in the stacked state. The capacitor elements 6, the anode terminal 12, and the cathode terminal 13 are configured to be covered with a synthetic resin 14 except for the lower faces of the anode terminal 12 and the cathode terminal 13.

As illustrated in FIGS. 2 and 3, each capacitor element 6 has a dielectric oxide film 2 and a cathode layer 3 formed over the surface of an aluminum foil 1, which serves as an anode body and is a valve metal. The cathode layer 3 comprises a solid electrolyte layer 3 a made of a polythiophene-based conductive polymer, a carbon layer 3 b, and a silver paint layer 3 c. A portion thereof in which the cathode layer 3 is formed over the dielectric oxide film 2 forms a cathode portion 8, and a portion thereof in which the cathode layer 3 is not formed forms an anode portion 7. A plurality of sheets of the capacitor elements 6 with such a configuration is stacked on top of one another, and the anode portions 7 of the adjacent capacitor elements 6 are weld-secured to one another while the cathode portions 8 of the adjacent capacitor elements 6 are adhesive-bonded to one another by conductive adhesive 18, whereby the multi-layered solid electrolytic capacitor 10 is formed. It should be noted that as illustrated in FIGS. 1 and 2, the dimensions of the multi-layered solid electrolytic capacitor are designed as follows; the length L1 of the cathode portions 8 is 3.8 mm, the length L2 of the anode portions 7 is 2.2 mm, the width L3 of the capacitor elements 6 is 3.5 mm, and the height L4 of the multi-layered solid electrolytic capacitor is 1.5 mm. In FIG. 2, reference numeral 20 designates a contact position with which a resistance welding rod is brought into contact.

Here, as illustrated in FIG. 4, in the capacitor element 6 used in the multi-layered solid electrolytic capacitor 10, a first stress alleviating slit 16 and a second stress alleviating slit 17 are provided in the vicinity of a boundary 15 between the cathode portion 8 and the anode portion 7 (i.e., in between the boundary 15 and the contact position 20 of the resistance welding rod) in the anode terminal 12 side surface of the anode portion 7 (i.e., in the lower surface thereof). The first stress alleviating slit 16 is designed to have a width L5 of 200 μm, a depth L6 of 30 μm, and a distance L7 from the boundary 15 of 300 μm, while the second stress alleviating slit 17 is designed to have a width L8 of 200 μm, a depth L9 of 30 μm, and a distance L10 from the boundary 15 of 700 μm. Since the stress alleviating slits 16 and 17 exist in this way, the anode portion 7 bends at the stress alleviating slits 16 and 17, as illustrated in FIG. 5. Thus, the bending stress that acts on the boundary 15 between the anode portion 7 and the cathode portion 8 or on the vicinity thereof reduces, and therefore, the stresses that act on that part reduces accordingly. As a result, it becomes possible to prevent the increase in leakage current of the capacitor and the defects due to short circuits, which result from the cracks that develop at the boundary 15 between the anode portion 7 and the cathode portion 8 or in the anode portion 7 that is in the vicinity thereof.

(Manufacturing Method of Multi-Layered Solid Electrolytic Capacitor)

First, a method of manufacturing a capacitor element 6 is illustrated. This method is the same as a conventional method.

Specifically, an aluminum foil 1 was subjected to a formation process in an aqueous solution of an adipic acid or the like at a predetermined concentration with a predetermined voltage to form a dielectric oxide film 2 made of a metal oxide. Thereafter, the aluminum foil was immersed to a predetermined position in a mixture solution of 3,4-ethylenedioxythiophene, ferric p-toluenesulfonate, and 1-butanol, to form a solid electrolyte layer 3 made of a conductive polymer, 3,4-ethylenedioxythiophene, on the dielectric oxide film 2 by a chemical oxidative polymerization. Next, the aluminum foil 1 on which the solid electrolyte layer had been formed was immersed in a solution in which carbon powder was diffused in an aqueous solution or an organic solvent, and then dried at a predetermined temperature for a predetermined time. This process was repeated several times to form a carbon layer 4. Finally, a silver paint layer 5 was formed on the surface of the carbon layer 4, whereby a capacitor element 6 was prepared.

Subsequently, prior to stacking and welding of a plurality of the capacitor elements 6, a first stress alleviating slit 16 and a second stress alleviating slit 17 were formed in each of the capacitor elements 6. Specifically, the formation of the slits was conducted by applying a laser beam to a vicinity of the boundary 15 between the cathode portion 8 and the anode portion 7 in the anode terminal 12 side surface of the anode portion 7 under the following laser conditions.

Laser conditions

-   -   Laser power: 3 W     -   Laser beam diameter: 200 μm

Next, as illustrated in FIG. 6, the anode portion 7 of the capacitor element 6 was connected to the anode terminal 12 by resistance welding, and the cathode portion 8 of the capacitor element 6 was adhesive-bonded to the cathode terminal 13 with a conductive adhesive 17. A plurality of sheets of capacitor elements 6 was stacked on top of one another by using resistance welding and the conductive adhesive 17. Lastly, the stack was sealed by an exterior resin 14 to complete a 16 V-10 μF multi-layered solid electrolytic capacitor 10.

Second Embodiment

A multi-layered solid electrolytic capacitor according to a second embodiment is described in detail with reference to FIG. 7. FIG. 7 is a plan view of a capacitor element according to the second embodiment.

What is different from the foregoing first embodiment is that, as illustrated in FIG. 7, a stress alleviating hole 22 is provided in the vicinity of the boundary 15 between the cathode portion 8 and the anode portion 7 (i.e., in between the boundary 15 and a contact position 20 of the resistance welding rod), in place of the first stress alleviating slit 16 and the second stress alleviating slit 17. This stress alleviating hole 22 forms an oblong shape, and it is formed so that its major axis 23 is parallel to the boundary 15 between the cathode portion 8 and the anode portion 7. The length L13 of the stress alleviating hole 22 along the major axis 23 is designed to be 1.3 mm and the distances L14 and L15 from the edges are both 1.1 mm. The length L17 of the stress alleviating hole 22 along its minor axis 24 is designed to be 500 μm and the distance L16 from the above-described boundary 15 is 300 μm.

Here, the stress alleviating hole 22 was formed by applying a laser beam to a vicinity of the boundary 15 between the cathode portion 8 and the anode portion 7 in the anode terminal 12 side surface of the anode portion 7 under the following laser conditions.

Laser conditions

-   -   Laser power: 8 W     -   Laser beam diameter: 200 μm

Since the stress alleviating hole 22 exists in this way in place of the stress alleviating slits 16 and 17, the anode portion 7 likewise bends at the stress alleviating hole 22. Thus, the bending stress that acts on the boundary 15 between the anode portion 7 and the cathode portion 8 or on the vicinity thereof reduces, and therefore, the stresses that act on that part reduces accordingly. As a result, it becomes possible to prevent the increase in leakage current of the capacitor and the defects due to short circuits, which result from the cracks that develop at the boundary 15 between the anode portion 7 and the cathode portion 8 or in the anode portion 7 that is in the vicinity thereof.

Moreover, since the hole is provided between the contact position 20 of the resistance welding rod and the boundary 15 between the anode and cathode portions 7 and 8, the heat applied to the resistance welding rod can be prevented from escaping toward the cathode portion 8. As a result, the welding can be accomplished with a less heat quantity, so the advantageous effect of improved weldability is exhibited additionally.

EXAMPLES First Working Example Example 1

A multi-layered solid electrolytic capacitor fabricated in the same manner as described in the foregoing first embodiment in the Best Mode for Carrying out the Invention was used as the multi-layered solid electrolytic capacitor of Example 1.

The multi-layered solid electrolytic capacitor in this manner is hereinafter referred to as an inventive capacitor A1.

Example 2

A multi-layered solid electrolytic capacitor was fabricated in the same manner as in the inventive capacitor A1, except that, in each of the capacitor elements 6, the first stress alleviating slit 16 and the second stress alleviating slit 17 were provided in the vicinity of the boundary 15 between the cathode portion 8 and the anode portion 7 in the surface opposite the anode terminal 12 side surface of the anode portion 7 (i.e., in the upper surface), as illustrated in FIG. 8.

The multi-layered solid electrolytic capacitor in this manner is hereinafter referred to as an inventive capacitor A2.

Comparative Example 1

A multi-layered solid electrolytic capacitor was fabricated in the same manner as in the inventive capacitor A1, except that the first stress alleviating slit 16 and the second stress alleviating slit 17 were not provided, as illustrated in FIGS. 14 and 15.

The multi-layered solid electrolytic capacitor fabricated in this manner is hereinafter referred to as a comparative capacitor X1.

Comparative Example 2

A multi-layered solid electrolytic capacitor was fabricated in the same manner as in the inventive capacitor A1, except that the first stress alleviating slit 16 and the second stress alleviating slit 17 were not provided, and that a thermosetting epoxy resin was applied to the boundary 15 between the cathode portion 8 and the anode portion 7 and in the vicinity thereof.

The multi-layered solid electrolytic capacitor fabricated in this manner is hereinafter referred to as a comparative capacitor X2.

Comparative Example 3

A multi-layered solid electrolytic capacitor was fabricated in the same manner as in the inventive capacitor A1, except that the first stress alleviating slit 16 and the second stress alleviating slit 17 were not provided, and that a heat-resistant polyimide tape was adhered to the vicinity of the boundary 15 between the cathode portion 8 and the anode portion 7.

The multi-layered solid electrolytic capacitor fabricated in this manner is hereinafter referred to as a comparative capacitor X3.

Experiment

100 samples of each of the inventive capacitors A1 and A2 and the comparative capacitors X1 to X3 were prepared, and the leakage current values for each of the multi-layered solid electrolytic capacitors were determined prior to the leakage current repairing process (aging). The results are shown in Table 1.

TABLE 1 Compara- Compara- Compara- Leakage Inventive Inventive tive tive tive current (μA) capacitor capacitor capacitor capacitor capacitor 16 V · 40 s A1 A2 X1 X2 X3   -300 32 12 — — — 300-600 39 20 — 1 — 600-900 24 32 — 15 5  900-1200 4 20 — 23 10 1200-1500 1 8 — 13 16 1500-1800 — 6 18 24 13 1800-2100 — 2 37 7 12 2100-2400 — — 13 1 5 2400-2700 — — 10 2 1 2700-3000 — — 2 — 3 3000-   — — 15 14 35 Number of 0 0 5 7 10 short defectives

As clearly seen from Table 1, the comparative capacitor X1 showed very large leakage current values and caused short circuits, and although the comparative capacitors X2 and X3 showed slightly smaller leakage current values, the improvement effect was not sufficient and they also caused short circuits. In contrast, the inventive capacitors A1 and A2 exhibited sufficiently small leakage current values and caused no short circuits. In particular, it is understood that the leakage current values were remarkably small in the inventive capacitor A1, in which the stress alleviating slits are provided in the anode terminal-side surface of the anode portion.

It is believed that these results are attributed to the following reason. In the comparative capacitors X1 to X3, tensile stress and bending stress act on the boundary between the anode portion and the cathode portion or the vicinity thereof during the resistance welding and the stresses build up in that part. As a consequence, cracks develop at the boundary between the anode portion and the cathode portion or in the anode portion that is in the vicinity thereof, causing an increase in leakage current of the capacitor and capacitor defects due to short circuits. In contrast, in the inventive capacitors A1 and A2, the anode portion bends at the stress alleviating slits during the resistance welding; therefore, the bending stress that acts on the boundary between the anode portion and the cathode portion or the vicinity thereof reduces, and the stress that acts on that part reduces accordingly. Thus, it is believed that it becomes possible to prevent the increase in leakage current of the capacitor and the defects due to short circuits, which result from the cracks that develop at the boundary between the anode portion and the cathode portion or in the anode portion that is in the vicinity thereof.

Second Working Examples Example

A multi-layered solid electrolytic capacitor fabricated in the same manner as described in the foregoing second embodiment in the Best Mode for Carrying out the Invention was used as the multi-layered solid electrolytic capacitor of this example.

The multi-layered solid electrolytic capacitor in this manner is hereinafter referred to as an inventive capacitor B.

Comparative Example

The comparative capacitor X1 as described in Comparative Example 1 of the foregoing first working examples was used as a comparative example.

Experiment

20 samples of each of the inventive capacitor B and the comparative capacitor X1 were fabricated, and the numbers of cracks developed were determined for each of the multi-layered solid electrolytic capacitors after the stacking. The results are shown in Table 2. It should be noted that whether or not there were cracks was determined by observing the boundary between the cathode portion and the anode portion with a microscope.

TABLE 2 Comparative Capacitor Invention capacitor B capacitor X1 Number of samples in 0 14 which cracks developed Number of samples: 20 for each capacitor.

As clearly seen from Table 2, cracks were developed in a large number of samples of the comparative capacitor X1, but no cracks were observed in the samples of the inventive capacitor B.

It is believed that such results were obtained for the same reason as discussed in Experiment in the first working examples.

Other Embodiments

(1) Although all the capacitor elements were provided with the stress alleviating slits in the first working examples, it is possible that, for example, the capacitor element that is weld-secured to the anode terminal may be provided with no stress alleviating slit.

The reason is as follows. As illustrated in FIG. 5, the bend of the anode portion 7 of a capacitor element 6 is greater when the capacitor element 6 is more distant from the anode terminal 12. That is, referring to FIG. 5, tilt angle θ₁ of the anode portion 7 of the capacitor element 6 in the first layer (i.e., the anode portion 7 that is weld-secured to the anode terminal 12)<tilt angle θ₂ of the anode portion 7 of the capacitor element 6 in the second layer<tilt angle θ₃ of the anode portion 7 of the capacitor element 6 in the third layer<tilt angle θ₄ of the anode portion 7 of the capacitor element 6 in the fourth layer. Thus, in the capacitor element 6 of the first layer, the anode portion 7 does not bend, or the bend is very small even if it bends, at the time of resistance welding, so the problem is insignificant even if no stress alleviating slit is formed therein.

(2) Although two stress alleviating slits are provided in the first working examples, the invention is not limited to such a structure. Of course, as illustrated in FIG. 9, only one stress alleviating slit 16 may be provided, or three or more alleviating slits may be provided. In this case, it is desirable to employ the structure in which the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating slits therein.

(3) Although the stress alleviating slits are provided in only one surface in the first working examples, the invention is not limited to such a structure. It is of course possible to provide the stress alleviating slits in both surfaces.

(4) Although all the stress alleviating slits have the same width in the first working examples, the invention is not limited to such a structure. It is of course possible to employ a structure in which the more distant the anode portion is from the anode terminal, the wider the width of the stress alleviating slits. In addition, the stress alleviating slits may not necessarily be formed from one edge to the other edge of the anode portion, but may be formed in only a portion thereof.

(5) Although only one stress alleviating hole is provided in the second working examples, the invention is not limited to such a structure. Of course, as illustrated in FIG. 10, two stress alleviating holes 22 may be provided, or even three or more alleviating holes may be provided.

(6) Although only the stress alleviating hole is provided in the second working examples, the invention is not limited to such a structure. Of course, as illustrated in FIG. 11, stress alleviating slits may be provided so as to be connected to the opposing ends of the stress alleviating hole 22.

(7) Although all the stress alleviating holes have the same size in the second working examples, the invention is not limited to such a structure. It is of course possible to employ a structure in which the more distant the anode portion is from the anode terminal, the greater the size of the stress alleviating hole (i.e., in a stress alleviating hole that is positioned distant from the anode terminal, a structure in which the length along the major axis is greater, as illustrated in FIG. 11). Alternatively, it is possible to employ a structure in which all the stress alleviating holes are the same but the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating holes.

(8) Although all the capacitor elements were provided with the stress alleviating hole in the second working examples, it is possible that, for example, the capacitor element that is weld-secured to the anode terminal may be provided with no stress alleviating hole. The reason is the same as described in the foregoing (1).

(9) Although the stress alleviating hole has an oblong shape in the second working examples, the invention is not limited to such a structure. It is also possible that, for example, the stress alleviating hole have a perfect circular shape, or a rectangular shape as illustrated in FIG. 13. However, it is more desirable that an oblong shape is employed because, when a rectangular shape is employed, cracks may develop at the four corners.

(10) The laser powers and laser beam diameters adopted in the two working examples are not limited to the values as described above, but may be changed as appropriate taking into consideration the slit depth, the hole size, the anode body material, the production efficiency, and the like. In this case, it is preferable to employ a laser power of from about 5 W to about 80 W.

(11) The valve metal is not limited to aluminum as described above but may also be tantalum, niobium, and the like. The solid electrolyte layer is not limited to a polythiophene-based conductive polymer, but may also be one of a polypyrrole-based conductive polymer, a polyaniline-based conductive polymer, a polyfuran-based conductive polymer, and manganese dioxide.

INDUSTRIAL APPLICABILITY

The present invention is applicable to, for example, power supply circuits for mobile telephones, notebook computers, and PDAs.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a vertical cross-sectional view of a multi-layered solid electrolytic capacitor according to the first embodiment.

FIG. 2 is a plan view of a capacitor element used in the first embodiment.

FIG. 3 is a cross-sectional view taken along line A-A in FIG. 2.

FIG. 4 is a cross-sectional view illustrating a primary portion enlarged of a capacitor element used in the first embodiment.

FIG. 5 is a cross-sectional view illustrating a primary portion enlarged of the multi-layered solid electrolytic capacitor according to the first embodiment.

FIG. 6 is a plan view illustrating a manufacturing step of the multi-layered solid electrolytic capacitor according to the first embodiment.

FIG. 7 is a plan view of a capacitor element used in the second embodiment.

FIG. 8 is a cross-sectional view illustrating a modified example of a capacitor element used in the first embodiment.

FIG. 9 is a cross-sectional view illustrating another modified example of a capacitor element used in the first embodiment.

FIG. 10 is a plan view illustrating a modified example of a capacitor element used in the second embodiment.

FIG. 11 is a plan view illustrating another modified example of a capacitor element used in the second embodiment.

FIG. 12 is a plan view illustrating yet another modified example of a capacitor element used in the second embodiment.

FIG. 13 is a plan view illustrating still another modified example of a capacitor element used in the second embodiment.

FIG. 14 is a cross-sectional view of a conventional capacitor element.

FIG. 15 is a vertical cross-sectional view of a conventional multi-layered solid electrolytic capacitor.

DESCRIPTION OF REFERENCE NUMERALS

-   -   1: aluminum foil     -   2: dielectric oxide film     -   3: cathode layer     -   3 a: solid electrolyte layer     -   3 b: carbon layer     -   3 c: silver paint layer     -   6: capacitor element     -   7: anode portion     -   8: cathode portion     -   10: multi-layered solid electrolytic capacitor     -   16: first stress alleviating slit     -   17: second stress alleviating slit     -   22: stress alleviating hole 

1-12. (canceled)
 13. A multi-layered solid electrolytic capacitor comprising: a plurality of capacitor elements, each comprising an anode body having an anode portion and a cathode portion having a dielectric oxide film and a cathode layer formed in succession on a surface of the anode body, wherein the plurality of capacitor elements are stacked on top of one another, the anode portions of adjacent capacitor elements are welded each other, and the anode portion of one of the outermost capacitor elements is weld-secured to an anode terminal, the multi-layered solid electrolytic capacitor being characterized in that: a stress alleviating slit and/or a stress alleviating hole is/are formed in between a welded part and the boundary between the anode and cathode portions in at lease one of weld surfaces of the anode portion.
 14. The multi-layered solid electrolytic capacitor according to claim 13, wherein the stress alleviating hole forms an oblong shape.
 15. The multi-layered solid electrolytic capacitor according to claim 13, wherein the major axis of the stress alleviating slit or the stress alleviating hole is substantially parallel to the boundary between the anode and cathode portions.
 16. The multi-layered solid electrolytic capacitor according to claim 14, wherein the major axis of the stress alleviating slit or the stress alleviating hole is substantially parallel to the boundary between the anode and cathode portions.
 17. The multi-layered solid electrolytic capacitor according to claim 13, wherein the stress alleviating slit is formed in an anode terminal-side surface of the weld surfaces of the anode portion.
 18. The multi-layered solid electrolytic capacitor according to claim 15, wherein the stress alleviating slit is formed in an anode terminal-side surface of the weld surfaces of the anode portion.
 19. The multi-layered solid electrolytic capacitor according to claim 13, wherein the stress alleviating slit or the stress alleviating hole is formed in the capacitor elements other than the capacitor element weld-secured to the anode terminal.
 20. The multi-layered solid electrolytic capacitor according to claim 14, wherein the stress alleviating slit or the stress alleviating hole is formed in the capacitor elements other than the capacitor element weld-secured to the anode terminal.
 21. The multi-layered solid electrolytic capacitor according to claim 15, wherein the stress alleviating slit or the stress alleviating hole is formed in the capacitor elements other than the capacitor element weld-secured to the anode terminal.
 22. The multi-layered solid electrolytic capacitor according to claim 13, wherein the stress alleviating slit or the stress alleviating hole is so formed that the more distant the anode portion is from the anode terminal, the greater the area of the stress alleviating slit or the stress alleviating hole in the weld surface.
 23. The multi-layered solid electrolytic capacitor according to claim 14, wherein the stress alleviating slit or the stress alleviating hole is so formed that the more distant the anode portion is from the anode terminal, the greater the area of the stress alleviating slit or the stress alleviating hole in the weld surface.
 24. The multi-layered solid electrolytic capacitor according to claim 15, wherein the stress alleviating slit or the stress alleviating hole is so formed that the more distant the anode portion is from the anode terminal, the greater the area of the stress alleviating slit or the stress alleviating hole in the weld surface.
 25. The multi-layered solid electrolytic capacitor according to claim 13, comprising at least one capacitor element in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed.
 26. The multi-layered solid electrolytic capacitor according to claim 14, comprising at least one capacitor element in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed.
 27. The multi-layered solid electrolytic capacitor according to claim 15, comprising at least one capacitor element in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed.
 28. The multi-layered solid electrolytic capacitor according to claim 25, wherein, when the multi-layered solid electrolytic capacitor comprises a plurality of capacitor elements in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed, the stress alleviating slits or the stress alleviating holes are so formed that the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating slits or the stress alleviating holes.
 29. The multi-layered solid electrolytic capacitor according to claim 26, wherein, when the multi-layered solid electrolytic capacitor comprises a plurality of capacitor elements in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed, the stress alleviating slits or the stress alleviating holes are so formed that the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating slits or the stress alleviating holes.
 30. The multi-layered solid electrolytic capacitor according to claim 27, wherein, when the multi-layered solid electrolytic capacitor comprises a plurality of capacitor elements in which a plurality of the stress alleviating slits or a plurality of the stress alleviating holes is formed, the stress alleviating slits or the stress alleviating holes are so formed that the more distant the anode portion is from the anode terminal, the greater the number of the stress alleviating slits or the stress alleviating holes.
 31. The multi-layered solid electrolytic capacitor according to claim 13, wherein, when the multi-layered solid electrolytic capacitor comprises both the stress alleviating slit and the stress alleviating hole, the stress alleviating slit is provided so as to be joined to the stress alleviating hole.
 32. The multi-layered solid electrolytic capacitor according to claim 14, wherein, when the multi-layered solid electrolytic capacitor comprises both the stress alleviating slit and the stress alleviating hole, the stress alleviating slit is provided so as to be joined to the stress alleviating hole.
 33. The multi-layered solid electrolytic capacitor according to claim 15, wherein, when the multi-layered solid electrolytic capacitor comprises both the stress alleviating slit and the stress alleviating hole, the stress alleviating slit is provided so as to be joined to the stress alleviating hole.
 34. A method of manufacturing a multi-layered solid electrolytic capacitor, comprising: a first step of preparing capacitor elements each comprising an anode portion and a cathode portion in which a dielectric oxide film and a cathode layer are formed successively over a surface of an anode body; a second step of forming a stress alleviating slit and/or a stress alleviating hole in at least one weld surface of the anode portion; a third step of weld-securing an anode terminal to the anode portion of one of the capacitor elements; and a fourth step of, in a state where another capacitor element is stacked on the one of the capacitor element weld-secured the anode terminal, weld-securing anode portions of adjacent capacitor elements to each other.
 35. The method of manufacturing a multi-layered solid electrolytic capacitor according to claim 34, wherein, in the second step, the stress alleviating slit and/or the stress alleviating hole is/are formed by a laser application method.
 36. The method of manufacturing a multi-layered solid electrolytic capacitor according to claim 34, wherein, in the second step, the stress alleviating hole is formed in a weld surface of the anode portion and the stress alleviating slit is formed in at least one weld surface of the anode portion so as to be joined to the stress alleviating hole.
 37. The method of manufacturing a multi-layered solid electrolytic capacitor according to claim 35, wherein, in the second step, the stress alleviating hole is formed in a weld surface of the anode portion and the stress alleviating slit is formed in at least one weld surface of the anode portion so as to be joined to the stress alleviating hole. 